KR101371605B1 - Coupling devices for underwater pump - Google Patents

Abstract

The present invention relates to a coupling device for a submersible propeller pump, which couples a submersible pump with a column pipe that drains a fluid stored in a tank. The coupling device for a submersible propeller pump is used to couple a submersible pump with a column pipe that drains a fluid stored in a tank, and comprises: a pump support part which protrudes inwardly from an inner circumference of the column pipe and on which the submersible pump is put; a fixing pipe which is installed around the inner circumference of the column pipe, and guides the movement of the submersible pump and supports the submersible pump when the submersible pump is installed; an edge part which protrudes outwardly the submersible pump so as to be put on the pump support part; and an insert groove which is formed in the edge part and into which the fixing pipe is inserted. Therefore, the coupling device for a submersible propeller pump according to the present invention can strengthen the support force of the submersible pump installed inside the column pipe, thereby preventing the deviation of the submersible pump from the pump support part, and absorb vibration generated from the submersible pump, thereby preventing the damage of the submersible pump or the column pipe and inhibiting the generation of noise.

Description

Coupling devices for underwater pump

The present invention relates to a coupling device of an underwater livestock pump for coupling an underwater pump to a column pipe for discharging the fluid stored in the reservoir to the outside.

In general, the submersible pump is a device that is located in the water of the fluid stored in the reservoir to discharge the fluid stored in the reservoir to the outside.

The submersible pump includes a driving unit including a rotor and a stator, a frame sealing the driving unit, and an impeller rotating and driven by the driving unit to rotate the impeller, so that the driving unit rotates against the centrifugal force generated by the impeller. Thereby sucking and discharging the stored fluid in the reservoir.

On the other hand, the submersible pump is provided in the storage tank is installed in the interior of the column pipe for discharging the fluid, or is installed in the form that is connected to the discharge pipe is formed smaller in diameter than the column pipe for discharging the fluid.

In this case, when the submersible pump is installed in the discharge pipe, the submersible pump is easily installed because the submersible pump is installed at the bottom of the reservoir, whereas the submersible pump is difficult to fix when the submersible pump is installed in the column pipe.

In order to solve such a problem, there has been disclosed a "installation structure of an underwater propeller pump" of Korean Patent Publication No. 10-1990-0014765 (published date: August 04, 1993).

The installation structure of the conventional underwater propeller pump is to install the pump on the inner bottom of the column pipe, on the outer side of the pump casing to install a rotation preventing device consisting of a stopper and a stopper coupled to the bottom of the packing pipe, The bottom of the pump casing is seated on the top of the seat with the packing installed, and a rotation preventing device is provided between the plurality of stop reinforcing pieces. It is configured to be located.

The installation structure of the conventional underwater propeller pump having the above-described configuration can easily install the underwater propeller pump, prevent the rotation of the underwater propeller pump and improve the airtightness of the underwater propeller pump.

However, when the underwater propeller pump is driven, severe vibrations are generated by the rotational force of the motor located on the upper portion of the underwater propeller pump, and the vibration of the underwater propeller pump is separated from the sheet part.

 In addition, fatigue accumulates in the column pipe due to vibration, and fatigue accumulates in a portion where the column pipe and the underwater propeller pump are connected, thereby causing problems such as damage of the column pipe and the underwater propeller pump.

In addition, the underwater propeller pump has a problem such as noise generated by the vibration of the column pipe.

The present invention is to solve the above problems, the problem to be solved by the present invention is to strengthen the bearing capacity of the submersible pump installed in the column pipe to prevent the submerged pump from the pump support, the submersible pump or column pipe It is to provide a coupling device of the underwater livestock pump that can prevent damage, and the generation of noise.

The coupling device of the underwater livestock pump according to an embodiment of the present invention for achieving the above object is a fastening device of the underwater pump for coupling the water pump to the column pipe for discharging the fluid stored in the reservoir to the outside, the column pipe A pump support part protruding inward from the inner circumference of the pump to cover the submersible pump, a fixed pipe supporting the submersible pump while guiding movement during installation of the submersible pump, and the pump catching part It includes an edge portion protruding outwardly of the submersible pump so as to span, and a fitting groove formed in the edge portion is fitted with the fixed pipe.

The edge portion may further include a pipe support portion extending upwardly or downwardly around a portion of the fitting groove so that the contact area with the fixed pipe is widened.

The pipe support part may include a vibration absorbing pad provided on a surface in contact with the fixed pipe to prevent vibration of the submersible pump from being transmitted to the fixed pipe.

The vibration absorbing pad may be formed in an embossed shape.

The plurality of fixed pipes may be installed radially around the inner circumference of the column pipe.

A vibration absorbing ring may be further disposed between the column pipe and the submersible pump to prevent vibration of the submersible pump from being transmitted to the column pipe.

The vibration absorbing ring may include a first vibration absorbing ring positioned between the pump support part and the edge part.

The vibration absorbing ring may include a second vibration absorbing ring located between the pump support and the submersible pump.

According to the present invention, the fixed pipe coupled to the rim is coupled to the column pipe so that the submersible pump can be firmly fixed to the column pipe to prevent the submerged pump from leaving the pump support by vibration of the submersible pump.

In addition, the pipe support portion can further improve the support force of the pipe support portion by widening the area where the fixed pipe contacts the edge portion.

In addition, the pipe support portion is provided with a vibration absorbing pad to prevent the vibration generated while the driving unit is transmitted to the fixed pipe to improve the holding force that the fixed pipe can support the rim portion while noise generated by the underwater pump Can be reduced.

In addition, when the rotation axis of the drive unit rotates, the vibration is generated in the submersible pump, and the first vibration absorbing ring and the second vibration absorbing ring absorb the vibration to prevent the vibration generated in the underwater pump from being transmitted to the column pipe. Can improve the confidentiality at the same time.

1 is a side view showing a state in which a coupling device of an underwater livestock pump according to an embodiment of the present invention is installed inside a column pipe.
FIG. 2 is an enlarged view of an enlarged portion "A" of FIG. 1.
3 is a perspective view showing a state in which a fixed pipe that is a component of the coupling device of the underwater livestock pump according to the embodiment of the present invention is coupled to the rim.
Figure 4 is a perspective view showing the pipe supporter components of the coupling device of the underwater livestock pump according to an embodiment of the present invention.
5 is a cross-sectional view taken along the line II of FIG. 1.
FIG. 6 is an enlarged view illustrating part “B” of FIG. 5.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

First, the coupling device 100 of the underwater livestock pump according to the embodiment of the present invention can be applied to various types of pumps to generate the earth output by rotating the impeller 210 by the rotational force of the driving means, for example, a motor or an engine. And, it will be described in this specification as an example applied to the submersible pump 200.

The underwater pump in the embodiment of the present invention means an underwater livestock pump.

As shown in FIG. 1, the coupling device 100 of the underwater livestock pump according to the embodiment of the present invention may include an underwater pump 200.

The submersible pump 200 may suck the fluid and discharge the sucked fluid.

That is, the submersible pump 200 is fixedly installed in a vertical state inside the column pipe 10 provided to discharge the fluid stored in the reservoir to the outside through the column pipe 10 to the outside of the reservoir through the column pipe 10. Can be discharged.

The submersible pump 200 may include a driving unit 220.

The driving unit 220 may generate power by receiving power. Meanwhile, the driving unit 220 may include a stator 221 and a rotor 223.

The stator 221 is formed in a ring shape, the coil may be wound to generate magnetic force with an external power source, and the stator 221 may be fixed to an inner circumferential surface of the frame 230 to be described below.

The rotor 223 is rotated by the magnetic force generated by the stator 221. The rotor 223 is formed in a drum shape, and a rotation shaft 225 is provided at the center thereof and inserted into the inner circumference of the stator 221.

The driving unit 220 configured as described above may rotate the rotating shaft 225 in a form in which the rotor 223 rotates by an induced current when a magnetic force is generated in the stator 221 by receiving external electricity.

Here, since the driving unit 220 may be implemented by a known motor, a detailed description thereof will be omitted, and the configuration of the driving unit 220 may be variously configured by a known motor having various forms.

The submersible pump 200 may include a frame 230.

The frame 230 protects the driving unit 220 and seals the driving unit 220 in a state where only one end of the rotating shaft 225 protrudes to prevent the fluid from flowing into the driving unit 220.

The submersible pump 200 may include an impeller 210.

The impeller 210 may suck and discharge the fluid, and is coupled to the rotating shaft 225 protruding to the outside of the frame 230, and thus to the rotational force of the driving unit 220, more specifically, the rotational force of the rotor 223. It can rotate by.

On the other hand, the impeller 210 in the present invention is not limited to the structure and shape of the impeller 210 because the known impeller 210 of various forms can be used.

The submersible pump 200 may include a casing 231. The casing 231 is coupled to the lower end of the frame 230, is formed in a form surrounding the outer periphery of the impeller 210 to suck the fluid to the lower end of the impeller 210, the upper part of the impeller 210 As a result, the sucked fluid can be discharged.

On the other hand, the inner circumferential surface of the casing 231 is formed in such a way that the central portion protrudes inward so as to be spaced apart from the outer circumference of the impeller 210 by a minimum distance to increase the suction force of the impeller 210 and at the same time the The flow can be smooth.

The outer surface of the casing 231 may be coupled to the inner circumferential surface of the column pipe 10 to support the submersible pump 200 inside the column pipe 10.

As shown in FIG. 2, the coupling device 100 of the underwater livestock pump according to the embodiment of the present invention may include a pump support 110.

The pump support unit 110 may be positioned at the end of the column pipe 10 so as to support the submersible pump 200 in the column pipe 10 and protrude inwardly from the inner circumference thereof to be coupled to the column pipe 10.

Here, the pump support 110 is formed in a ring shape is inserted into the casing 231 of the submersible pump 200 more specifically the submersible pump 200 in the center of the casing 231 around the upper end of the pump support 110 ) Can be spread over.

As shown in FIG. 3, the coupling device 100 of the underwater livestock pump according to the embodiment of the present invention may include an edge portion 120.

The rim 120 has a circumference larger than the circumference of the submersible pump 200 on the outer surface of the submersible pump 200 and more specifically the outer surface of the casing 231 so that the submersible pump 200 spans the pump support 110. It may be formed to protrude to have.

As such, the coupling device 100 of the underwater livestock pump is provided with a pump support 110 and a rim 120 so that when the submersible pump 200 is installed inside the column pipe 10, the rim 120 is provided. The submersible pump 200 may be installed inside the column pipe 10 in such a way as to span the pump support 110.

As shown in Figure 4 to 5, the coupling device 100 of the underwater livestock pump according to an embodiment of the present invention may include a fitting groove (140).

The fitting groove 140 has a groove having a shape corresponding to the shape of the circumference of the fixing pipe 130 is formed in the edge portion 120 so that the fixing pipe 130 to be described below is fitted to the fixing pipe 130. The edge portion 120 may be fixed to the fixing pipe 130 in a form of being coupled to the groove 140.

Coupling device 100 of the underwater livestock pump according to an embodiment of the present invention may include a pipe support (121).

The pipe support part 121 may be formed to extend upward or downward around a part of the fitting groove 140 so that the contact area with the fixed pipe 130 to be described below is widened.

On the other hand, the pipe support portion 121 may include a vibration absorbing pad 123.

The vibration absorbing pad 123 is a fixed pipe 130 of the pipe support 121 to prevent the vibration generated while the driving unit 220 of the submersible pump 200 is transmitted to the fixed pipe 130 The vibration absorbing pad 123 may be provided at a surface to be in contact with the pipe support 121.

Here, the vibration absorbing pad 123 is, for example, strong adhesion such as EVA (Ethylene Vinyl Acetate), soft PVC (Poly Vinyl Choloride), silicone, NBR (Nityl Butadiene Rubber), rubber, and the vibration generated in the water pump 200 It may be formed of a material that can absorb the.

In addition, the vibration absorbing pad 123 may be formed in an embossed shape on the surface to which the fixed pipe 130 is in contact so as to increase the absorbing power for absorbing the vibration generated in the submerged pump 200.

 Coupling device 100 of the underwater livestock pump according to an embodiment of the present invention may include a fixed pipe (130).

The fixed pipe 130 guides the movement when the submersible pump 200 is installed, and can firmly support the submersible pump 200 so that the submersible pump 200 does not flow due to vibration.

On the other hand, the fixed pipe 130 is formed in a rod shape, the fixed pipe 130 may be coupled in the form of welding to the inner circumference of the column pipe 10 may support the edge portion 120 (see FIG. 6).

In addition, a plurality of stationary pipes 130 may be radially installed around the inner circumference of the comum pipe so that the supporting force for supporting the submersible pump 200 may be improved.

The coupling device 100 of the underwater livestock pump according to the embodiment of the present invention may include a vibration absorbing ring 150.

The vibration absorbing ring 150 is positioned between the column pipe 10 and the submersible pump 200 to prevent the vibration generated from the driving unit 220 of the submersible pump 200 from being transmitted to the column pipe 10. Can be.

In addition, the vibration absorbing ring 150 has a shape corresponding to the outer circumferential surface of the vibration absorbing ring 150 so that the vibration absorbing ring 150 can be coupled to the column pipe 10 or the submersible pump 200 in a forced fit manner. Grooves may be formed.

Here, the vibration absorbing ring 150 is, for example, strong adhesion, such as EVA (Ethylene Vinyl Acetate), soft PVC (Poly Vinyl Choloride), silicone, NBR (Nityl Butadiene Rubber), rubber, and the vibration generated in the water pump 200 It may be formed of a material that can absorb the.

Meanwhile, the vibration absorbing ring 150 may include a first vibration absorbing ring 151 and a second vibration absorbing ring 153.

The first vibration absorbing ring 151 is located between the pump support 110 and the edge 120 to support the edge 120 in the pump support 110 to absorb the vibration transmitted to the edge 120 Vibration may be prevented from being transmitted to the column pipe 10.

At this time, the surface facing the pump support 110 of the edge portion 120 or the surface facing the edge 120 of the pump support 110 is a groove of a shape corresponding to the outer peripheral surface of the first vibration absorption ring 151 The first recess 152 is formed so that the first vibration absorbing ring 151 is tightly coupled to the first recess 152 to absorb the vibration transmitted to the edge portion 120 and improve airtightness.

The second vibration absorbing ring 153 is positioned between the pump support 110 and the submersible pump 200, more specifically, the casing 231 of the submersible pump 200 to support the casing 231 at the pump support 110. By absorbing the vibration transmitted to the casing 231 it can prevent the vibration is transmitted to the column pipe (10).

At this time, the second surface of the shape corresponding to the outer circumferential surface of the second vibration absorption ring 153 on the surface facing the pump support portion 110 of the casing 231 or the surface facing the casing 231 of the pump support 110. The groove 154 is formed so that the second vibration absorbing ring 153 is tightly coupled to the second groove 154 to absorb the vibration transmitted to the casing 231 and improve airtightness.

The operation and effect between the above-described respective constitutions will be described.

In the coupling device 100 of the underwater livestock pump according to the embodiment of the present invention, the pump support part 110 is provided at the end of the column pipe 10, and the casing 231 is provided on the outer surface of the casing 231 of the underwater pump 200. The edge portion 120 having a circumference larger than the circumference of the) is formed.

In addition, the rim portion 120 has a fitting groove 140 formed in a shape and a counterpart around the fixed pipe 130, and the rim portion 120 has a fitting groove so that the contact area with the fixed pipe 130 is widened ( The pipe support 121 is formed by extending upward or downward around a portion of the 140.

On the other hand, the pipe support portion 121, the outer surface is formed in the embossed vibration absorbing pad 123 is coupled to the surface where the fixed pipe 130 of the pipe support portion 121 is in contact, the column pipe 10 is an underwater pump 200 The fixed pipe 130 is coupled to the inner circumference of the column pipe 10 so as to guide and support the same.

Meanwhile, the first vibration absorbing ring 151 is coupled to the first recess 152 and the second vibration absorbing ring 153 is coupled to the second recess 154.

The coupling device 100 of the submerged livestock pump configured as described above inserts the submersible pump 200 into the column pipe 10 in a state where the fixed pipe 130 is fitted into the fitting groove 140 so that the submersible pump 200 is provided. The fixed pipe 130 guides the submersible pump 200 to move along the fixed pipe 130 to the pump support 110.

In addition, the frame portion 120 of the submersible pump 200 is positioned inside the column pipe 10 and the casing 231 of the submersible pump 200 is positioned in the water tank so that the edge portion 120 spans the pump support 110. The submersible pump 200 is fixed in the column pipe 10 in a losing form.

At this time, a first vibration absorbing ring 151 and a second vibration absorbing ring 153 are provided between the submersible pump 200 and the pump support part 110 so that the submersible pump 200 and the pump support part 110 are closely coupled. Can be.

In this way, the coupling device 100 of the underwater livestock pump couples the underwater pump to the column pipe 10 so that the driving unit 220 rotates the rotary shaft 225 while the impeller 210 rotates while the centrifugal force of the impeller 210 is rotated. As a result, the fluid is sucked into the lower end of the impeller 210, and the sucked fluid is discharged into the upper part of the impeller 210.

At this time, when the rotating shaft 225 of the driving unit 220 rotates, the vibration is generated in the submersible pump 200. The first vibration absorbing ring 151 and the second vibration absorbing ring 153 absorb vibrations. The vibration generated in the submersible pump 200 may be prevented from being transmitted to the column pipe 10, and the airtightness may be improved.

In addition, since the edge portion 120 is supported by the fixed pipe 130 so that the submersible pump 200 can be firmly fixed to the column pipe 10, the submersible pump 200 is caused by the vibration of the submersible pump 200. It is possible to prevent the departure from the pump support 110.

In this case, the pipe support part 121 may further improve the support force of the pipe support part 121 by widening the area where the fixed pipe 130 contacts the edge part 120.

In addition, the pipe support 121 is provided with a vibration absorbing pad 123 to prevent the vibration generated while the driving unit 220 rotates to the fixed pipe 130 to prevent the fixed pipe 130 is the edge portion 120 At the same time to improve the bearing capacity to support the noise generated by the submersible pump 200 can be reduced.

Therefore, the coupling device 100 of the underwater livestock pump according to the present invention is to strengthen the bearing capacity of the underwater pump 200 installed in the column pipe 10 that the submersible pump 200 is separated from the pump support 110 It can be prevented, and by absorbing the vibration generated in the submerged pump 200 can prevent damage and noise generation of the submersible pump 200 or column pipe 10.

Although the preferred embodiment of the present invention has been described above, the scope of the present invention is not limited only to the specific embodiment described above, and those skilled in the art may appropriately change within the scope described in the claims of the present invention. This will be possible.

10: column pipe
100: coupling device of the underwater livestock pump 110: pump support
120: edge portion 121: pipe support portion
123: vibration absorbing pad 130: fixed pipe
140: fitting groove 150: vibration absorption ring
151: first vibration absorbing ring 152: first groove portion
153: second vibration absorption ring 154: second groove portion
200: submersible pump 210: impeller
220: drive unit 221: stator
223: rotor 225: rotation axis
230: frame 231: casing

Claims (8)

As a coupling device of the submerged livestock pump for coupling the submersible pump to the column pipe for discharging the fluid stored in the reservoir to the outside,
A pump support part protruding inward from the inner circumference of the column pipe to cover the submersible pump,
A fixed pipe installed around the inner circumference of the column pipe to guide movement during the installation of the submersible pump and to support the submersible pump;
An edge portion projecting outward of the submersible pump so as to span the pump support portion;
A coupling device of the submerged condensation pump, characterized in that it comprises a fitting groove formed in the edge portion is fitted with the fixed pipe. The method of claim 1,
The border portion
And a pipe support portion extending upwardly or downwardly around a portion of the fitting groove so that the contact area with the fixed pipe is widened. 3. The method of claim 2,
The pipe support portion
And a vibration absorbing pad provided on a surface in contact with the fixed pipe to prevent vibration of the submersible pump from being transmitted to the fixed pipe. The method of claim 3, wherein
The vibration absorbing pad
Coupling device of the underwater livestock pump, characterized in that formed in the embossed shape. The method of claim 1,
The fixed pipe
Combined device of the submerged condensation pump, characterized in that a plurality of radially installed around the inner circumference of the column pipe. delete The method according to claim 1,
Located between the column pipe and the submersible pump further comprises a vibration absorption ring to prevent the vibration of the submersible pump is transmitted to the column pipe,
The vibration absorption ring
And a first vibration absorbing ring positioned between the pump support and the edge portion. The method according to claim 1,
Located between the column pipe and the submersible pump further comprises a vibration absorption ring to prevent the vibration of the submersible pump is transmitted to the column pipe,
The vibration absorption ring
And a second vibration absorbing ring positioned between the pump support and the submersible pump.

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